// This file is part of the AliceVision project.
// Copyright (c) 2016 AliceVision contributors.
// Copyright (c) 2012 openMVG contributors.
// This Source Code Form is subject to the terms of the Mozilla Public License,
// v. 2.0. If a copy of the MPL was not distributed with this file,
// You can obtain one at https://mozilla.org/MPL/2.0/.

#pragma once

/**
 ** @file standard image filtering functions :
 ** - X,Y derivatives using : Central difference, Sobel filter, Scharr filter
 ** - Gaussian blur
 **/

 //------------------
//-- Bibliography --
//------------------
//- [1] "A Scheme for Coherence-Enhancing Diffusion Filtering with Optimized Rotation Invariance."
//- Authors: Joachim Weickert and Hanno Scharr.
//- Date: September 2002.
//- Journal : Journal of Visual Communication and Image Representation.

#include "aliceVision/image/convolution.hpp"

namespace aliceVision {
namespace image {

  /**
   ** Compute X-derivative using central difference
   ** @param img Input image
   ** @param out Output image
   ** @param normalize true if kernel must be scaled by 1/2
   **/
  template< typename Image >
  void ImageXDerivative( const Image & img , Image & out , const bool normalize = true)
  {
    Vec3 kernel( -1.0, 0.0, 1.0);

    if( normalize )
      kernel *= 0.5 ;

    ImageHorizontalConvolution( img , kernel , out) ;
  }


  /**
   ** Compute Y-derivative using central difference
   ** @param img Input image
   ** @param out Output image
   ** @param normalize true if kernel must be normalized
   **/
  template< typename Image >
  void ImageYDerivative( const Image & img , Image & out , const bool normalize = true)
  {
    Vec3 kernel( -1.0, 0.0, 1.0) ;

    if( normalize )
      kernel *= 0.5 ;

    ImageVerticalConvolution( img , kernel , out ) ;
  }


  /**
   ** Compute X-derivative using 3x3 Sobel kernel
   ** @param img Input image
   ** @param out Output image
   ** @param normalize true if kernel must be scaled by 1/8
   **/
  template< typename Image >
  void ImageSobelXDerivative( const Image & img , Image & out , const bool normalize = true)
  {
    Vec3 kernel_horiz( -1.0, 0.0, 1.0) ;

    if( normalize )
      kernel_horiz *= 0.5 ;

    Vec3 kernel_vert( 1.0, 2.0, 1.0) ;

    if( normalize )
      kernel_vert *= 0.25 ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out ) ;
  }


  /**
   ** Compute Y-derivative using 3x3 Sobel kernel
   ** @param img Input image
   ** @param out Output image
   ** @param normalize true if kernel must be scaled by 1/8
   **/
  template< typename Image >
  void ImageSobelYDerivative( const Image & img , Image & out , const bool normalize = true)
  {
    Vec3 kernel_horiz( 1.0, 2.0, 1.0) ;

    if( normalize )
      kernel_horiz *= 0.25 ;

    Vec3 kernel_vert( -1.0, 0.0, 1.0) ;

    if( normalize )
      kernel_vert *= 0.5 ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }

  /**
   ** Compute X-derivative using 3x3 Scharr kernel
   ** @param img Input image
   ** @param out Output image
   ** @param normalize true if kernel must be scaled by 1/32
   **/
  template< typename Image >
  void ImageScharrXDerivative( const Image & img , Image & out , const bool normalize = true)
  {
    Vec3 kernel_horiz( -1.0, 0.0, 1.0) ;

    if( normalize )
      kernel_horiz *= 0.5 ;

    Vec3 kernel_vert( 3.0, 10.0, 3.0) ;

    if( normalize )
      kernel_vert *= 1.0 / 16.0 ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }

  /**
   ** Compute Y-derivative using 3x3 Scharr filter
   ** @param img Input image
   ** @param out Output image
   ** @param normalize true if kernel must be scaled by 1/32
   **/
  template< typename Image >
  void ImageScharrYDerivative( const Image & img , Image & out , const bool normalize = true)
  {
    Vec3 kernel_horiz( 3.0, 10.0, 3.0) ;

    if( normalize )
      kernel_horiz *= 1.0 / 16.0 ;

    Vec3 kernel_vert( -1.0, 0.0, 1.0) ;

    if( normalize )
      kernel_vert *= 0.5 ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }


  /**
   ** Compute X-derivative using scaled Scharr filter
   ** @param img Input image
   ** @param out Output image
   ** @param scale scale of filter (1 -> 3x3 filter ; 2 -> 5x5, ...)
   ** @param bNormalize true if kernel must be normalized
   **/
  template< typename Image >
  void ImageScaledScharrXDerivative( const Image & img , Image & out , const int scale , const bool bNormalize = true)
  {
    const int kernel_size = 3 + 2 * ( scale - 1 ) ;

    Vec kernel_vert( kernel_size ) ;
    Vec kernel_horiz( kernel_size ) ;

    /*
    General X-derivative function
                                | -1   0   1 |
    D = 1 / ( 2 h * ( w + 2 ) ) | -w   0   w |
                                | -1   0   1 |
    */

    kernel_horiz.fill( 0.0 ) ;
    kernel_horiz( 0 )               = -1.0 ;
    // kernel_horiz( kernel_size / 2 ) = 0.0 ;
    kernel_horiz( kernel_size - 1 ) = 1.0 ;

    // Scharr parameter for derivative
    const double w = 10.0 / 3.0 ;

    kernel_vert.fill( 0.0 ) ;
    kernel_vert( 0 )               = 1.0 ;
    kernel_vert( kernel_size / 2 ) = w ;
    kernel_vert( kernel_size - 1 ) = 1.0 ;

    if( bNormalize )
      kernel_vert *= 1.0 / ( 2.0 * scale * ( w + 2.0 ) ) ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }



  /**
   ** Compute Y-derivative using scaled Scharr filter
   ** @param img Input image
   ** @param out Output image
   ** @param scale scale of filter (1 -> 3x3 filter ; 2 -> 5x5, ...)
   ** @param bNormalize true if kernel must be normalized
   **/
  template< typename Image >
  void ImageScaledScharrYDerivative( const Image & img , Image & out , const int scale , const bool bNormalize = true)
  {
    /*
    General Y-derivative function
                                | -1  -w  -1 |
    D = 1 / ( 2 h * ( w + 2 ) ) |  0   0   0 |
                                |  1   w   1 |

    */
    const int kernel_size = 3 + 2 * ( scale - 1 ) ;

    Vec kernel_vert( kernel_size ) ;
    Vec kernel_horiz( kernel_size ) ;

    // Scharr parameter for derivative
    const double w = 10.0 / 3.0 ;


    kernel_horiz.fill( 0.0 ) ;
    kernel_horiz( 0 )               = 1.0 ;
    kernel_horiz( kernel_size / 2 ) = w ;
    kernel_horiz( kernel_size - 1 ) = 1.0 ;

    if( bNormalize )
      kernel_horiz *= 1.0 / ( 2.0 * scale * ( w + 2.0 ) ) ;

    kernel_vert.fill( 0.0 ) ;
    kernel_vert( 0 ) = - 1.0 ;
    // kernel_vert( kernel_size / 2 ) = 0.0 ;
    kernel_vert( kernel_size - 1 ) = 1.0 ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }


  /**
   ** Compute (isotropic) gaussian filtering of an image using filter width of k * sigma
   ** @param img Input image
   ** @param sigma standard deviation of kernel
   ** @param out Output image
   ** @param k confidence interval param - kernel is width k * sigma * 2 + 1 -- using k = 3 gives 99% of gaussian curve
   ** @param border_mgmt either BORDER_COPY or BORDER_CROP to tell what to do with borders
   **/
  template< typename Image >
  void ImageGaussianFilter( const Image & img , const double sigma , Image & out , const int k = 3)
  {
    // Compute Gaussian filter
    const int k_size    = (int) 2 * k * sigma + 1 ;
    const int half_k_size = k_size / 2 ;

    const double exp_scale = 1.0 / ( 2.0 * sigma * sigma ) ;

    // Compute 1D Gaussian filter
    Vec kernel_horiz( k_size ) ;

    double sum = 0 ;
    for( int i = 0 ; i < k_size ; ++i )
    {
      const double dx = (i - half_k_size) ;
      kernel_horiz( i ) = exp( - dx * dx * exp_scale ) ;
      sum += kernel_horiz( i ) ;
    }

    // Normalize kernel (to have \sum_i kernel_horiz( i ) = 1 and avoid energy loss)
    const double inv = 1.0 / sum ;
    for( int i = 0 ; i < k_size ; ++i )
    {
      kernel_horiz( i ) *= inv ;
    }

    // Vertical kernel is the same as the horizontal one
    const Vec & kernel_vert = kernel_horiz ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }

  /**
   ** @brief Compute 1D gaussian kernel of specified width
   ** @param size Size of kernel (0 for automatic window)
   ** @param sigma Gaussian scale
   ** @return Kernel using specified parameters
   **/
  Vec ComputeGaussianKernel(const std::size_t size, const double sigma);

  /**
   ** Compute gaussian filtering of an image using user defined filter widths
   ** @param img Input image
   ** @param sigma standard deviation of kernel
   ** @param out Output image
   ** @param kernel_size_x Size of horizontal kernel (must be an odd number or 0 for automatic computation)
   ** @param kernel_size_y Size of vertical kernel (must be an add number or 0 for automatic computation)
   **/
  template< typename Image >
  void ImageGaussianFilter( const Image & img , const double sigma , Image & out ,
                            const size_t kernel_size_x , const size_t kernel_size_y)
  {
    assert( kernel_size_x % 2 == 1 || kernel_size_x == 0 ) ;
    assert( kernel_size_y % 2 == 1 || kernel_size_y == 0 ) ;

    const Vec kernel_horiz = ComputeGaussianKernel( kernel_size_x , sigma ) ;
    const Vec kernel_vert  = ComputeGaussianKernel( kernel_size_y , sigma ) ;

    ImageSeparableConvolution( img , kernel_horiz , kernel_vert , out) ;
  }

} // namespace image
} // namespace aliceVision
